High speed differential receiver with an integrated multiplexer input

ABSTRACT

A high-speed interface between a first network component and a second network component includes a positive voltage input (VINP) and a negative voltage input (VINN) for receiving an input data signal from the first network component; the positive voltage input (VINP) coupled to a negative output circuit (OUTN) and the negative voltage input (VINN) by a positive input bus and a negative input bus, the negative voltage input (VINN) also coupled to a positive output circuit (OUTP). Implementing the high-speed interface calls for applying a bias to the a positive input bus and a negative input bus to periodically multiplex a data signal, thus providing a common receiving path for functional data and wrap data of the data signal.

TRADEMARKS

IBM® is a registered trademark of International Business MachinesCorporation, Armonk, N.Y., U.S.A. Other names used herein may beregistered trademarks, trademarks or product names of InternationalBusiness Machines Corporation or other companies.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to high-speed interfaces for computer networksystems.

2. Description of the Background

When designing a high-speed interface between network components, thereis typically a need for wrapping data back through transmitter andreceiver circuitry. The wrapping back of data provides for verifyingfunctionality as a “built in self test” (BIST). Preferably, a wrap pathoperates at functional speeds so that as much of the functional path aspossible is used with out a performance penalty. One existing (priorart) approach for implementing the wrap path is depicted in FIG. 1.

Referring to FIG. 1, the illustration therein depicts prior artcircuitry for verifying functionality of a high-speed interfaceimplemented in a receive path 9. In this embodiment, a wrap path 5 for areceiver 8 is a mirror of a functional data path 6. The wrap path 5 ismultiplexed in to the data path 6 after a second data receive stage.This design, or designs similar thereto, have typically been applied sothat the data path 6 was not impaired by circuitry for the wrap path 5.Unfortunately, such designs have at least one drawback in that theactual circuitry of the data path 6 is not used. A second drawback isrealized by having a multiplexer 4 in the data path 6, which causesadded latency and jitter in a data signal.

What is needed is a high-speed interface between network components thatprovides for wrapping back of data and for verifying functionalitythereof. Preferably, the high-speed interface makes use of an existingdata path to provide for accurate communication, without causing latencyand jitter in the data signal.

SUMMARY OF THE INVENTION

Disclosed is a high speed interface for communicating a data signalhaving functional data and wrap data between a first network componentand a second network component, the interface including a positivevoltage input (VINP) and a negative voltage input (VINN) for receivingan input data signal from the first network component; the positivevoltage input (VINP) coupled to a negative output circuit (OUTN) and thenegative voltage input (VINN) by a positive input bus and a negativeinput bus, the negative voltage input (VINN) also coupled to a positiveoutput circuit (OUTP); the negative output circuit (OUTN) and thepositive output circuit (OUTP) coupled to a common operating point;wherein a transmission gate in the negative output circuit (OUTN)provides a negative output data signal from the common operating pointfor the second network component and another transmission gate in thepositive output circuit (OUTP) provides a positive output data signalfrom the common operating point for the second network component.

Also disclosed is a method for providing a high-speed differentialmultiplexed data signal, the method for selecting a high speed interfacefor communicating between a first network component and a second networkcomponent a data signal having functional data and wrap data, theinterface including a positive voltage input (VINP) and a negativevoltage input (VINN) for receiving an input data signal from the firstnetwork component; the positive voltage input (VINP) coupled to anegative output circuit (OUTN) and the negative voltage input (VINN) bya positive input bus and a negative input bus, the negative voltageinput (VINN) also coupled to a positive output circuit (OUTP); thenegative output circuit (OUTN) and the positive output circuit (OUTP)coupled to a common operating point; wherein a transmission gate in thenegative output circuit (OUTN) provides a negative output data signalfrom the common operating point for the second network component andanother transmission gate in the positive output circuit (OUTP) providesa positive output data signal from the common operating point for thesecond network component; wherein a biasing positive field effecttransistor (PFET) is coupled to the positive input bus and a biasingnegative field effect transistor (NFET) is coupled to the negative inputbus; applying a bias to at least one of the biasing PFET and the biasingNFET for periodically multiplexing the data signal.

Further disclosed is a high speed interface for communicating a datasignal having functional data and wrap data between a first networkcomponent and a second network component, the interface including apositive voltage input (VINP) coupled to a gate of a positive fieldeffect transistor (PFET) and a gate of an negative field effecttransistor (NFET) and a negative voltage input (VINN), coupled to a gateof another positive field effect transistor (PFET) and a gate of anothernegative field effect transistor (NFET); a negative output circuit(OUTP) comprising a plurality of NFET and a plurality of PFET and apositive output circuit (OUTP) comprising another plurality of NFET andanother plurality of PFET; wherein one of a source and a drain of thePFET in the positive voltage input (VINP) is coupled to a couplingbetween the NFET in the plurality of NFET and one of a source and adrain of the NFET in the positive voltage input (VINP) is coupled to acoupling between the PFET in the plurality of PFET; wherein one of asource and a drain of the another PFET in the negative voltage input(VINN) is coupled to a coupling between the NFET in the anotherplurality of NFET and one of a source and a drain of the another NFET inthe negative voltage input (VINN) is coupled to a coupling between thePFET in the another plurality of PFET, wherein, the remaining one of thesource and the drain for the another PFET is coupled to the remainingone of the source and the drain for the PFET in the positive voltageinput (VINP) to form a positive input bus and the remaining one of thesource and the drain for the another NFET is coupled to the remainingone of the source and the drain for the NFET in the positive voltageinput (VINP) to form a negative input bus; wherein a gate for each ofthe NFET and each of the PFET in the negative output circuit (OUTN) andthe positive output circuit (OUTP) are coupled to a common operatingpoint; wherein the negative output circuit (OUTN) comprises atransmission gate coupled to the common operating point and at least oneNFET of the plurality and at least one PFET of the plurality and thepositive output circuit (OUTP) comprises another transmission gatecoupled to the common operating point and at least one NFET of theanother plurality and at least one PFET of the another plurality;wherein one of a source and a drain for a positive bias device iscoupled to the positive input bus and one of a source and a drain for anegative bias device is coupled to the negative input bus; and, whereinfunctional data and wrap data from the first network component issubmitted to the positive voltage input (VINP) and the negative voltageinput (VINN) and passed to the second network component via the negativeoutput circuit (OUTP) and the positive output circuit (OUTP).

Additional features and advantages are realized through the techniquesof the present invention. Other embodiments and aspects of the inventionare described in detail herein and are considered a part of the claimedinvention. For a better understanding of the invention with advantagesand features, refer to the description and to the drawings.

TECHNICAL EFFECTS

As a result of the summarized invention, technically we have achieved asolution which provides for a high-speed differential receiver havingintegrated multiplexer input. The receiver provides for receiving wrapdata and functional data in a common path thus providing for improvedspeed, reduced latency and jitter as well as improved stability in aninterface between a first network component and a second networkcomponent over prior art interfaces implementing a dual data path.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter which is regarded as the invention is particularlypointed out and distinctly claimed in the claims at the conclusion ofthe specification. The foregoing and other objects, features, andadvantages of the invention are apparent from the following detaileddescription taken in conjunction with the accompanying drawings inwhich:

FIG. 1 illustrates one example of a prior art high-speed interfacehaving a wrap back path;

FIG. 2 illustrates one example of a wrap back path in accordance withthe teachings herein;

FIG. 3 illustrates aspects of input and output signals for a high-speedinterface; and,

FIG. 4 illustrates one example of a modification to the circuit depictedin FIG. 3.

The detailed description explains the preferred embodiments of theinvention, together with advantages and features, by way of example withreference to the drawings.

DETAILED DESCRIPTION OF THE INVENTION

Turning now to the drawings in greater detail, it will be seen that inFIG. 2 there is a high-speed interface 10 according to the presentinvention. The high-speed interface 10 includes a multiplexing function14 within the first stage of a receiver 18. In this embodiment, themultiplexing function 14 is included within a first stage of thereceiver 18. Implementing a wrap path 15 in this fashion provides forusing a data path 16 as the receive path 19. This design eliminates theuncertainty of the prior art, which makes use of parallel paths.Further, by removing a traditional multiplexer 4 from the receive path19 (the multiplexer 4 selecting which path is propogated to an output) areduction in both latency and jitter is realized.

In order to clearly distinguish aspects of data, as discussed herein, adata signal includes functional data 11 as well as wrap data 12. Thefunctional data 11 includes many types of data for communication throughthe high-speed interface 10. Wrap data 12 includes the portion of datafor wrapping back through the high-speed interface 10, and typicallyprovides for verifying functionality through a “built in self test”(BIST). One skilled in the art will recognize that in various instancesfunctional data 11 and wrap data 12 may include various relationshipssuch as being interchangeable or a subset of one or the other.

In typical embodiments, the high-speed interface 10 makes use of fieldeffect transistors (FETs). FETs include three terminals, or leads. Theterminals include a drain, a source and a gate. FETs can switch signalsof either polarity on the source terminal or the drain terminal if thesignal amplitude is significantly less than the gate swing amplitude, asFET devices are typically symmetrical (about the source terminal and thedrain terminal). This makes FETs suitable for a variety of switchingtasks, including switching analog signals between paths (multiplexing).

FIG. 3 provides a typical embodiment of a circuit implementing thehigh-speed interface 10. In this embodiment, an input stage of thereceiver 18 accommodates inputs of wrap data 12. In FIG. 3, the inputstage of the receiver 18 has a positive voltage input (VINP) 33 and anegative voltage input (VINN) 34. In this embodiment, the VINP 33includes a positive field effect transistor (PFET) TP6 and a negativefield effect transistor (NFET) TN6. A gate for each of TP6 and TN6 arecoupled to receive a positive input signal. The VINN 34 similarlyincludes a positive field effect transistor (PFET) TP7 and a negativefield effect transistor (NFET) TN7. Also similarly, a gate for each ofTP7 and TN7 are coupled to receive a negative input signal.

In this exemplary circuit, a common operating point 30 is formed by acommon coupling of a negative output circuit 31 and a positive outputcircuit 32. In this illustration, the negative output circuit 31includes positive field effect transistor (PFET) devices TP1, TP2, withnegative field effect transistor (NFET) devices TN1, TN2, while thepositive output side includes PFET devices TP3, TP4 and NFET devicesTN3, TN4. The common coupling is formed by the coupling of a gate foreach of the PFET and the NFET in the negative output circuit 31 witheach of the PFET and the NFET in the positive output circuit 32.

In this embodiment of the negative output circuit 31, a coupling of oneof a drain and a source for TN1 to one of the drain and the source forTN2 is made. The remaining lead of TN2 (either one of the drain or thesource) is coupled to an output node OUTN. Likewise, a coupling of oneof a drain and a source for TP1 to one of the drain and the source forTP2 is made. The remaining lead of TP2 (either one of the drain or thesource) is coupled to an output node OUTN. The output node OUTN iscoupled to the common operating point 30 by a transmission gate TG1.

In this embodiment of the positive output circuit 32, a coupling of oneof a drain and a source for TN3 to one of the drain and the source forTN4 is made. The remaining lead of TN4 (either one of the drain or thesource) is coupled to an output node OUTP. Likewise, a coupling of oneof a drain and a source for TP3 to one of the drain and the source forTP4 is made. The remaining lead of TP4 (either one of the drain or thesource) is coupled to an output node OUTP. The output node OUTP iscoupled to the common operating point 30 by a transmission gate TG2.

The output signals include a negative output signal through the outputnode OUTN and a positive output signal through the output node OUTP. Thetransmission gates TG1 and TG2 are coupled to the common operating point30 and provide a feedback path 31 for the wrap data 12.

The positive voltage input 33 is coupled to the negative output circuit31. This coupling is realized, in part, by coupling one of a drain and asource for the PFET TP6 to the coupling between TN1 and TN2. Thecoupling is completed by coupling one of a drain and a source for theNFET TP6 to the coupling between TP1 and TP2.

The negative voltage input 34 is coupled to the positive output circuit32. This coupling is realized, in part, by coupling one of a drain and asource for the PFET TP7 to the coupling between TN3 and TN4. Thecoupling is completed by coupling one of a drain and a source for theNFET TN7 to the coupling between TP3 and TP4.

The positive voltage input 33 is also coupled to the negative voltageinput 34 by a positive input bus 35 and a negative input bus 36. To formthe positive input bus 35, a remaining lead (one of the source and thedrain) for TP6 is coupled to the remaining lead (one of the source andthe drain) for TP7. Likewise, to form the negative input bus 36 theremaining lead (one of the source and the drain) for TN6 is coupled tothe remaining lead (one of the source and the drain) for TN7.

Coupled to the positive input bus 35 and the negative input bus 36 are aPFET TP5 and an NFET TN5, respectively. The bias devices TP5 and TN5provide a current path to swing the output nodes OUTP and OUTN. The biasfor PFET TP5 is turned on by input EN_BAR and the bias for NFET TN5 isturned on by input EN.

It should be noted that the terms “positive voltage input,” “negativevoltage input,” “negative output circuit,” “positive output circuit”“positive input bus,” and “negative input bus” are presented and definedmerely for convenience of referencing and to lend an understanding tothe teachings. These terms are not intended to limit aspects of thedesign or the teachings in any way and are only provided to introduceand better describe aspects of the high-speed interface 10.

The exemplary embodiment depicted in FIG. 3 can be modified to provide ahigh-speed differential multiplexer. One exemplary modification callsfor using the bias devices PFET TP5 and NFET TN5 to select a primaryreceive path (data path 16) and periodically disabling the bias devicesto provide a wrap data path 15 as a second path. This modificationprovides one way to implement the logical built-in-self-test BISTfunction.

FIG. 4 depicts an embodiment that is a modification to the circuitdepicted in FIG. 3. In this embodiment, a second input path is providedto pass the wrap data 12. In FIG. 4, the circuit for the high-speedinterface 10 is represented by PFET TP1 through PFET TP7 and NFET TN1through NFET TN7.

This embodiment includes WRAP_EN and WRAP_ENBAR inputs for selection ofa primary data path (receive) from the positive voltage input signal(VINP) and the negative voltage input signal (VINN). Alternatively, theWRAP_EN and WRAP_ENBAR inputs are provided for logic wrap inputs WRAP_Pand WRAP_N to propagate to OUTP and OUTN. In this embodiment, theWRAP_EN and WRAP_ENBAR inputs on devices PFETs TPW2, TPW4 and NFETsTNW2, TNW4 are placed between the wrap input devices PFETs TPW1, TPW3and NFETs TNW1, TNW3 and the rest of the circuitry. This placementprovides isolation of the wrap input and limits degradation orcorruption of performance in the primary receive data path.

Typically, the high-speed interface 10 is used as a high-speeddifferential receiver with an integrated multiplexer input.

Although the exemplary embodiments depicted herein are illustrated ashardware implementations, it should be recognized that the capabilitiesof the present invention may be implemented in software, firmware,hardware or some combination thereof. As one example, one or moreaspects of the present invention can be included in an article ofmanufacture (e.g., one or more computer program products) having, forinstance, computer usable media. The media has embodied therein, forinstance, computer readable program code means for providing andfacilitating the capabilities of the present invention. The article ofmanufacture can be included as a part of a computer system or soldseparately.

Additionally, at least one program storage device readable by a machine,tangibly embodying at least one program of instructions executable bythe machine to perform the capabilities of the present invention can beprovided.

The flow diagrams depicted herein are just examples. There may be manyvariations to these diagrams or the steps (or operations) describedtherein without departing from the spirit of the invention. Forinstance, the steps may be performed in a differing order, or steps maybe added, deleted or modified. All of these variations are considered apart of the claimed invention.

While the preferred embodiment to the invention has been described, itwill be understood that those skilled in the art, both now and in thefuture, may make various improvements and enhancements which fall withinthe scope of the claims which follow. These claims should be construedto maintain the proper protection for the invention first described.

1. A high speed interface for communicating a data signal comprisingfunctional data and wrap data between a first network component and asecond network component, the interface comprising: a positive voltageinput (VINP) and a negative voltage input (VINN) for receiving an inputdata signal from the first network component; the positive voltage input(VINP) coupled to a negative output circuit (OUTN) and the negativevoltage input (VINN) by a positive input bus and a negative input bus,the negative voltage input (VINN) also coupled to a positive outputcircuit (OUTP); the negative output circuit (OUTN) and the positiveoutput circuit (OUTP) coupled to a common operating point; wherein atransmission gate in the negative output circuit (OUTN) provides anegative output data signal from the common operating point for thesecond network component and another transmission gate in the positiveoutput circuit (OUTP) provides a positive output data signal from thecommon operating point for the second network component.
 2. Theinterface as in claim 1, wherein each of the positive voltage input(VINP) and the negative voltage input (VINN) comprise a negative fieldeffect transistor (NFET) and a positive field effect transistor (PFET).3. The interface as in claim 1, isolated sources of wrap data arecoupled to each of the PFET of the positive voltage input (VINP), theNFET of the positive voltage input (VINP), the PFET of the negativevoltage input (VINN), and the NFET of the negative voltage input (VINN).4. The interface as in claim 1, wherein the negative output circuit(OUTN) comprises a plurality of negative field effect transistor (NFET)and a plurality of positive field effect transistor (PFET).
 5. Theinterface as in claim 1, wherein the positive output circuit (OUTP)comprises a plurality of negative field effect transistor (NFET) and aplurality of positive field effect transistor (PFET).
 6. The interfaceas in claim 1, wherein a positive field effect transistor (PFET) iscoupled to the positive input bus and a negative field effect transistor(NFET) is coupled to the negative input bus.
 7. The interface as inclaim 1, wherein the interface provides a common path for the functionaldata and the wrap data.
 8. A method for providing a high-speeddifferential multiplexed data signal, the method comprising: selecting ahigh speed interface for communicating between a first network componentand a second network component a data signal comprising functional dataand wrap data, the interface comprising a positive voltage input (VINP)and a negative voltage input (VINN) for receiving an input data signalfrom the first network component; the positive voltage input (VINP)coupled to a negative output circuit (OUTN) and the negative voltageinput (VINN) by a positive input bus and a negative input bus, thenegative voltage input (VINN) also coupled to a positive output circuit(OUTP); the negative output circuit (OUTN) and the positive outputcircuit (OUTP) coupled to a common operating point; wherein atransmission gate in the negative output circuit (OUTN) provides anegative output data signal from the common operating point for thesecond network component and another transmission gate in the positiveoutput circuit (OUTP) provides a positive output data signal from thecommon operating point for the second network component; wherein abiasing positive field effect transistor (PFET) is coupled to thepositive input bus and a biasing negative field effect transistor (NFET)is coupled to the negative input bus; applying a bias to at least one ofthe biasing PFET and the biasing NFET for periodically multiplexing thedata signal.
 9. The method as in claim 8, wherein the multiplexingprovides for a common path for the functional data and the wrap data.10. The method as in claim 8, wherein the providing comprises providinga built in self test for the high speed interface.
 11. A high speedinterface for communicating a data signal comprising functional data andwrap data between a first network component and a second networkcomponent, the interface comprising: a positive voltage input (VINP)coupled to a gate of a positive field effect transistor (PFET) and agate of an negative field effect transistor (NFET) and a negativevoltage input (VINN), coupled to a gate of another positive field effecttransistor (PFET) and a gate of another negative field effect transistor(NFET); a negative output circuit (OUTP) comprising a plurality of NFETand a plurality of PFET and a positive output circuit (OUTP) comprisinganother plurality of NFET and another plurality of PFET; wherein one ofa source and a drain of the PFET in the positive voltage input (VINP) iscoupled to a coupling between the NFET in the plurality of NFET and oneof a source and a drain of the NFET in the positive voltage input (VINP)is coupled to a coupling between the PFET in the plurality of PFET;wherein one of a source and a drain of the another PFET in the negativevoltage input (VINN) is coupled to a coupling between the NFET in theanother plurality of NFET and one of a source and a drain of the anotherNFET in the negative voltage input (VINN) is coupled to a couplingbetween the PFET in the another plurality of PFET, wherein, theremaining one of the source and the drain for the another PFET iscoupled to the remaining one of the source and the drain for the PFET inthe positive voltage input (VINP) to form a positive input bus and theremaining one of the source and the drain for the another NFET iscoupled to the remaining one of the source and the drain for the NFET inthe positive voltage input (VINP) to form a negative input bus; whereina gate for each of the NFET and each of the PFET in the negative outputcircuit (OUTN) and the positive output circuit (OUTP) are coupled to acommon operating point; wherein the negative output circuit (OUTN)comprises a transmission gate coupled to the common operating point andat least one NFET of the plurality and at least one PFET of theplurality and the positive output circuit (OUTP) comprises anothertransmission gate coupled to the common operating point and at least oneNFET of the another plurality and at least one PFET of the anotherplurality; wherein one of a source and a drain for a positive biasdevice is coupled to the positive input bus and one of a source and adrain for a negative bias device is coupled to the negative input bus;and, wherein functional data and wrap data from the first networkcomponent is submitted to the positive voltage input (VINP) and thenegative voltage input (VINN) and passed to the second network componentvia the negative output circuit (OUTP) and the positive output circuit(OUTP).